ZEUS (particle detector)

Last updated July 26, 2023

ZEUS was a particle detector at the HERA (Hadron Elektron Ring Anlage) particle accelerator at the German national laboratory DESY in Hamburg. It began taking data in 1992 and was operated until HERA was decommissioned in June 2007. The scientific collaboration behind ZEUS consisted of about 400 physicists and technicians from 56 institutes in 17 countries.^[1]

The ZEUS detector comprised many different detector components, including a depleted uranium plastic-scintillator calorimeter, a central tracking detector (which was a wire chamber), a silicon microvertex detector and muon chambers. In addition, a solenoid provided a 1.43 T magnetic field. The ZEUS detector measured 12 m × 11 m × 20 m and weighed 3600 tons.^[2]

Like its partner experiment H1, the ZEUS experiment studied the internal structure of the proton through measurements of deep inelastic scattering by colliding leptons (electrons or positrons) with protons in the interaction point of ZEUS. These measurements were also used to test and study the Standard Model of particle physics as well as to search for particles beyond the Standard Model, laying the foundation to much of the science done at the Large Hadron Collider (LHC) at the CERN particle physics laboratory today.^[3]

Background

The German national laboratory DESY was founded in 1959 and started operating its first particle accelerator in 1964. Since then, it has been a highly regarded center for particle physics, photon science, astroparticle physics, and the development, construction and operation of particle accelerators. The design effort for ZEUS can be traced back to 1982.^[4] A Letter of Intent was submitted in 1985.^[5] The ZEUS detector was operational with the first collisions of the HERA collider in 1992. The last electron–proton collisions at ZEUS were recorded on 30 June 2007.^[6] The other multi-purpose experiment at the HERA collider was the competing H1 experiment. Since May 2012, the former ZEUS detector hall has been used as a lab space for the international European XFEL project.^[7]

Detector

The main components of the ZEUS detector were the tracking components, the calorimeter and the muon detectors.^[8] The purpose of the ZEUS detector was to collect data to allow the reconstruction of physics events in a consistent way so they can be analyzed.

Calorimeter

The ZEUS Calorimeter was a uranium scintillator based sampling calorimeter and divided into three main sections: the BCAL (Barrel CALorimeter), FCAL (Forward CALorimeter), and RCAL (Rear CALorimeter). Each section was subdivided transversely into towers, and longitudinally into EMC (Electro-Magnetic Calorimeter) or HAC (HAdronic Calorimeter). The smallest subdivision in the calorimeter was called a cell. Each cell was read out by two photomultiplier tubes (PMTs), which helped ensure that there were no holes in the coverage if one of the two PMTs failed.

Uranium was chosen as an absorber so that the calorimeter would be compensating.^[5] Electrons and photons deposit energy differently from hadrons, but in a compensating calorimeter the response (e) for an electromagnetic cascade is equal to the response (h) for a hadronic cascade of the same energy (i.e. e/h = 1).^[9] In the ZEUS calorimeter neutral pions interacted with uranium atoms to produce slow-moving neutrons which were captured by the scintillator and increased the hadronic signal. Another advantage of using uranium as the absorber was that the natural radioactivity allowed the calorimeter's sensitivity to be conveniently monitored.

Notes

↑ "Institutes taking part in the ZEUS Collaboration". The ZEUS Experiment.
↑ "HERA pointing the way" (PDF). DESY. Retrieved 4 May 2023.
↑ "Heuer, Rolf and Wagner, Alrecht: HERA leaves a rich legacy of knowledge". CERN Courier. Retrieved 4 May 2023.
↑ Electron-Proton Interaction Experiment (PDF) (Technical report). FermiLab. May 1982.
1 2 ZEUS Collaboration: K. Edwards; Edwards, K.; Kapitza, H. (June 1985). ZEUS: A Detector for HERA, Letter of Intent (Report).
↑ Harris, David (September 2007). "The End of the HERA Era". Symmetry Magazine. 04 (7). Retrieved 10 November 2011.
↑ "Research at Hamburg's Deepest Scientific Workplace Resumes". European XFEL. Retrieved 15 July 2015.
↑ "The ZEUS Detector: Status Report 1993". The ZEUS Experiment.
↑ Bock, Rudolf K. (9 April 1998). "Compensating Calorimeter" . Retrieved 10 November 2011.

External links

53°34′29″N9°53′44″E / 53.574603°N 9.89555°E / 53.574603; 9.89555

Related Research Articles

A gluon is an elementary particle that acts as the exchange particle for the strong force between quarks. It is analogous to the exchange of photons in the electromagnetic force between two charged particles. Gluons bind quarks together, forming hadrons such as protons and neutrons.

Particle physics or high energy physics is the study of fundamental particles and forces that constitute matter and radiation. The fundamental particles in the universe are classified in the Standard Model as fermions and bosons. There are three generations of fermions, although ordinary matter is made only from the first fermion generation. The first generation consists of up and down quarks which form protons and neutrons, and electrons and electron neutrinos. The three fundamental interactions known to be mediated by bosons are electromagnetism, the weak interaction, and the strong interaction.

DESY, short for Deutsches Elektronen-Synchrotron, is a national research centre for fundamental science located in Hamburg and Zeuthen near Berlin in Germany. It operates particle accelerators used to investigate the structure, dynamics and function of matter, and conducts a broad spectrum of interdisciplinary scientific research in four main areas: particle and high energy physics; photon science; astroparticle physics; and the development, construction and operation of particle accelerators. Its name refers to its first project, an electron synchrotron. DESY is publicly financed by the Federal Republic of Germany and the Federal States of Hamburg and Brandenburg and is a member of the Helmholtz Association of German Research Centres.

<span class="mw-page-title-main">Compact Muon Solenoid</span> One of the two general-purposes experiments at the CERNs Large Hadron Collider

<span class="mw-page-title-main">ATLAS experiment</span> CERN LHC experiment

ATLAS is the largest general-purpose particle detector experiment at the Large Hadron Collider (LHC), a particle accelerator at CERN in Switzerland. The experiment is designed to take advantage of the unprecedented energy available at the LHC and observe phenomena that involve highly massive particles which were not observable using earlier lower-energy accelerators. ATLAS was one of the two LHC experiments involved in the discovery of the Higgs boson in July 2012. It was also designed to search for evidence of theories of particle physics beyond the Standard Model.

H1 was a particle detector operated at the HERA collider at the German national laboratory DESY in Hamburg. The first studies for the H1 experiment were proposed in 1981. The H1 detector began operating together with HERA in 1992 and took data until 2007. It consisted of several different detector components, measured about 12 m × 15 m × 10 m and weighed 2800 tons. It was one of four detectors along the HERA accelerator.

The Large Electron–Positron Collider (LEP) was one of the largest particle accelerators ever constructed. It was built at CERN, a multi-national centre for research in nuclear and particle physics near Geneva, Switzerland.

The Underground Area 2 (UA2) experiment was a high-energy physics experiment at the Proton-Antiproton Collider — a modification of the Super Proton Synchrotron (SPS) — at CERN. The experiment ran from 1981 until 1990, and its main objective was to discover the W and Z bosons. UA2, together with the UA1 experiment, succeeded in discovering these particles in 1983, leading to the 1984 Nobel Prize in Physics being awarded to Carlo Rubbia and Simon van der Meer. The UA2 experiment also observed the first evidence for jet production in hadron collisions in 1981, and was involved in the searches of the top quark and of supersymmetric particles. Pierre Darriulat was the spokesperson of UA2 from 1981 to 1986, followed by Luigi Di Lella from 1986 to 1990.

HERA was a particle accelerator at DESY in Hamburg. It was operated from 1992 to 30 June 2007. At HERA, electrons or positrons were brought to collision with protons at a center-of-mass energy of 320 GeV. HERA was used mainly to study the structure of protons and the properties of quarks, laying the foundation for much of the science done at the Large Hadron Collider (LHC) at the CERN particle physics laboratory today. HERA is the only lepton–proton collider in the world to date and was on the energy frontier in certain regions of the kinematic range.

The Collider Detector at Fermilab (CDF) experimental collaboration studies high energy particle collisions from the Tevatron, the world's former highest-energy particle accelerator. The goal is to discover the identity and properties of the particles that make up the universe and to understand the forces and interactions between those particles.

The DØ experiment was a worldwide collaboration of scientists conducting research on the fundamental nature of matter. DØ was one of two major experiments located at the Tevatron Collider at Fermilab in Batavia, Illinois. The Tevatron was the world's highest-energy accelerator from 1983 until 2009, when its energy was surpassed by the Large Hadron Collider. The DØ experiment stopped taking data in 2011, when the Tevatron shut down, but data analysis is still ongoing. The DØ detector is preserved in Fermilab's DØ Assembly Building as part of a historical exhibit for public tours.

In particle physics, a hermetic detector is a particle detector designed to observe all possible decay products of an interaction between subatomic particles in a collider by covering as large an area around the interaction point as possible and incorporating multiple types of sub-detectors. They are typically roughly cylindrical, with different types of detectors wrapped around each other in concentric layers; each detector type specializes in particular particles so that almost any particle will be detected and identified. Such detectors are called "hermetic" because they are constructed so as the motion of particles are ceased at the boundaries of the chamber without any moving beyond due to the seals; the name "4π detector" comes from the fact that such detectors are designed to cover nearly all of the 4π steradians of solid angle around the interaction point; in terms of the standard coordinate system used in collider physics, this is equivalent to coverage of the entire range of azimuthal angle and pseudorapidity. In practice, particles with pseudorapidity above a certain threshold cannot be measured since they are too nearly parallel to the beamline and can thus pass through the detector. This limit on the pseudorapidity ranges which can be observed forms part of the acceptance of the detector ; broadly speaking, the main design objective of a hermetic detector is to maximise acceptance, i.e. to ensure that the detector is able to measure as large a phase space region as possible.

<span class="mw-page-title-main">COMPASS experiment</span>

The NA58 experiment, or COMPASS is a 60-metre-long fixed-target experiment at the M2 beam line of the SPS at CERN. The experimental hall is located at the CERN North Area, close to the French village of Prévessin-Moëns. The experiment is a two-staged spectrometer with numerous tracking detectors, particle identification and calorimetry. The physics results are extracted by recording and analysing the final states of the scattering processes. The versatile set-up, the use of different targets and particle beams allow the investigation of various processes. The main physics goals are the investigation of the nucleon spin structure and hadron spectroscopy. The collaboration consists of 220 physicists from 13 different countries, involving 28 universities and research institutes.

<span class="mw-page-title-main">L3 experiment</span>

The L3 experiment was one of the four large detectors on the Large Electron–Positron Collider (LEP). The detector was designed to look for the physics of the Standard Model and beyond. It started up in 1989 and stopped taking data in November 2000 to make room for construction of the Large Hadron Collider (LHC). Now, the ALICE detector sits in the cavern that L3 used to occupy, reusing L3's characteristic red octagonal magnet.

The CALICE collaboration is an R&D group of more than 280 physicists and engineers from around the world, working together to develop new, high performance detectors for high energy positron-electron experiments at future International Linear Collider (ILC). It is a part of the European EUDET project.

<span class="mw-page-title-main">NA62 experiment</span>

The NA62 experiment is a fixed-target particle physics experiment in the North Area of the SPS accelerator at CERN. The experiment was approved in February 2007. Data taking began in 2015, and the experiment is expected to become the first in the world to probe the decays of the charged kaon with probabilities down to 10⁻¹². The experiment's spokesperson is Cristina Lazzeroni. The collaboration involves 333 individuals from 30 institutions and 13 countries around the world.

Jonathan Mark Butterworth is a Professor of Physics at University College London (UCL) working on the ATLAS experiment at CERN's Large Hadron Collider (LHC). His popular science book Smashing Physics, which tells the story of the search for the Higgs boson, was published in 2014 and his newspaper column / blog Life and Physics is published by The Guardian.

A Totally Hermetic Electron-Nucleus Apparatus (ATHENA) is a proposed experiment at the future Electron Ion Collider (EIC), in Brookhaven National Laboratory, United States.

The MilliQan experiment is a small-scale detector experiment at CERN's Large Hadron Collider (LHC). MilliQan is not a separate CERN experiment but is handled as a CMS sub-detector, with a dedicated memorandum of understanding to define authorship and responsibilities. The goal of the MilliQan experiment is to detect millicharged particles: particles with charges much smaller than that of the electron. These particles are motivated by the existence of a dark photon, and discovery of millicharged particles would provide a first probe into the dark sector. The MilliQan prototype detector collected data during LHC Run 2 in 2018 and set competitive constraints on millicharged particle charges and masses. The upgraded Run 3 MilliQan detectors are scheduled to be installed in 2022.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Members-1] "Institutes taking part in the ZEUS Collaboration". The ZEUS Experiment.

[2] "HERA pointing the way" (PDF). DESY. Retrieved 4 May 2023.

[3] "Heuer, Rolf and Wagner, Alrecht: HERA leaves a rich legacy of knowledge". CERN Courier. Retrieved 4 May 2023.

[4] Electron-Proton Interaction Experiment (PDF) (Technical report). FermiLab. May 1982.

[ZEUSLOI-5] 1 2 ZEUS Collaboration: K. Edwards; Edwards, K.; Kapitza, H. (June 1985). ZEUS: A Detector for HERA, Letter of Intent (Report).

[6] Harris, David (September 2007). "The End of the HERA Era". Symmetry Magazine. 04 (7). Retrieved 10 November 2011.

[European_XFEL_news-7] "Research at Hamburg's Deepest Scientific Workplace Resumes". European XFEL. Retrieved 15 July 2015.

[ZEUSDetector-8] "The ZEUS Detector: Status Report 1993". The ZEUS Experiment.

[9] Bock, Rudolf K. (9 April 1998). "Compensating Calorimeter" . Retrieved 10 November 2011.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]